Hypolipidemic Effect and Antiatherogenic Potential of Pu-Erh Tea

Pu-Erh tea is a fermented tea produced in Yunnan area, a .... supplemented with 10% fetal calf serum (FCS) in 12-well culture dishes (3xl05 cell/well)...
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Chapter 5

Hypolipidemic Effect and Antiatherogenic Potential of Pu-Erh Tea 1

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Lucy Sun Hwang , Lan-Chi Lin , Nien-Tsu Chen , Huei-Chiuan Liuchang , and Ming-Shi Shiao 2

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Graduate Institute of Food Science and Technology, National Taiwan University, Taipei, Taiwan, Republic of China Department of Medical Research and Education, Veterans General Hospital, Taipei, Taiwan, Republic of China 2

Pu-Erh tea is a fermented tea produced in Yunnan area, a southwestern part of China. The manufacture of Pu-Erh tea involves natural fermentation and prolonged storage at ambient temperature. Lovastatin was identified in batches of Pu-Erh tea. This study demonstrated that uptake of Pu-Erh tea reduced plasma cholesterol and triacylglycerol in cholesterol-fed hamsters. Results also suggested that the cholesterol-lowering effect of Pu-Erh tea was caused by a combination of lovastatin and tea polyphenols. Although the content of EGCG was low, Pu-Erh tea yet exhibited strong antioxidant activities that scavenged DPPH radical and inhibited LDL oxidation in vitro and ex vivo. This study indicates that Pu-Erh tea drinking may reduce the risk factors in atherosclerosis-related ischemic heart disease.

© 2003 American Chemical Society In Oriental Foods and Herbs; Ho, C., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.

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88 Elevation of plasma cholesterol, particularly low-density lipoprotein cholesterol (LDL-C), is positively correlated with coronary heart disease (CHD), a major vascular disease predominantly causing by atherosclerosis (1,2). Recent studies have indicated that LDL oxidation, endothelial dysfunction, and inflammation play important roles in the molecular pathogenesis of atherosclerosis (3). Oxidized LDL (OxLDL) appears in the circulation and tends to infiltrate into the aortic endothelium (4). Antioxidants, which inhibit LDL oxidative modification, may reduce early atherogenesis and slow down the disease progression to an advanced stage (5). Tea (Camellia sinensis) is a very popular and widely consumed beverage in the world. The biological activities and pharmacological functions of tea natural components, particularly the polyphenols, have attracted great attention for years (6,7). Tea catechins decrease micellar solubility and intestinal absorption of cholesterol in rats (8). The cholesterol-lowering effect of (-)-epigallocatechin gallate (EGCG) (Figure 1), a major catechin in tea, on experimental hypercholesterolemia in rats has been reported. It indicates that the antihypercholesterolemic effect of EGCG is primarily due to the inhibition of absorption of exogenous cholesterolfromthe digestive tract and partly due to the enhanced elimination of endogenous cholesterol (9). Feeding of green and black teas reduce lipid peroxidation in rat liver and kidney (10). Epicatechin isomers from jasmine green tea and tea polyphenols inhibitfreeradical-induced cell lysis and oxidative damage to red blood cells (11,12). Green and black teas reduce LDL oxidizability and atherosclerosis in cholesterol-fed rabbits (73). EGCG and theaflavins from tea inhibit Cu induced LDL oxidation, a process involving cholesteryl ester degradation and apoB-100 fragmentation (14). The relative potency of five common tea polyphenols (flavan-3-ol derivatives) on Cu mediated oxidative modification of LDL follows the trend: EGCG>ECG>EC>C>EGC (75). The potency to inhibit LDL oxidation in vitro by green tea extract has also been compared with those of vitamin C and E. The antioxidant effect of green tea is not due to metal chelation (16). Ex vivo antioxidant effects of green tea and black tea have been demonstrated in human (17,18). Green tea is more potent in inhibiting LDL oxidation in vitro and ex vivo. At least one study has indicated that black tea consumption does not protect LDL from oxidation (19). Pu-Erh tea is a fermented tea produced in Yunnan area, a southwestern part of China. The manufacture of Pu-Erh tea involves natural fermentation and prolonged storage at an ambient temperature and high moisture environment. This tea has gained popularity recently. It is speculated that the ingredients in Pu-Erh tea can be originated from the tea leaves and their transformed products by endogenous enzymes. Besides, metabolites derived from the microorganisms, such as Aspergillus, and biotransformation products originated from tea may contribute to the biological activities of Pu-Erh tea. A previous study has indicated that Pu-Erh tea reduces plasma cholesterol and triacylglycerol in female Wistar rats (20). The findings suggest that Pu-Erh tea may ameliorate 2+

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In Oriental Foods and Herbs; Ho, C., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.

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Figure I. Structures of (-)-epigallocatechin-3-gallate (EGCG), lovastatin, βsitosterol, and trolox.

In Oriental Foods and Herbs; Ho, C., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.

90 hyperlipidemia and atherosclerosis. The potential of Pu-Erh tea to inhibit LDL oxidation has not been elucidated and compared with other teas. The content of catechins in Pu-Erh tea is significantly lower than those of green and black teas. It is less likely to attribute the beneficial effect to catechins. We therefore studied the effects of Pu-Erh tea on lipid metabolism in hamsters and the antioxidant potential to reduce LDL oxidation in vitro and ex vivo.

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Materials Cholesterol, β-sitosterol, l,l-Diphenyl-2-picrylhydrazyl (DPPH), 1,1,3,3tetramethoxypropane (TMP), bovine serum albumin (BSA), α-tocopherol, and retinyl acetate were purchased from Sigma (St Louis, MO). Pu-Erh tea was obtained from Yunnan, China. It was ground into powder (2.5 kg) and extracted with boiling water (1:10; w/v). The aqueous extract was filtered, concentrated, and lyophilized. The dry powder (designated as PET) was kept at -20 °C before use. The extraction yield was 29.2% (w/w). Human hepatoma cells (Hep G2) were obtainedfromthe cell bank, Veterans General Hospital-Taipei. Male, Golden Syrian hamsters (n=40) (body weight 116±5 g) were obtained from the Animal Center, National Science Council, Taiwan. Rodent chow (Purina 5001) was purchasedfromPurina.

Inhibition of Cholesterol Synthesis in Hep G2 Cells The potential of PET to inhibit cholesterol biosynthesis was determined by the inhibition of the incorporation of [2- H]acetate and R-[2- C]mevalonate into cholesterol (21). Human hepatoma cells (Hep G2) were cultured in DMEM supplemented with 10% fetal calf serum (FCS) in 12-well culture dishes (3xl0 cell/well) at 37 °C for 48 hours. After transferring to fresh medium, cells were treated with PET and labeled precursors ([2- H]acetate 2.5 μ α ; R-[2C]mevalonate, 1.3 μΟΊ). Lovastatin, in hydroxy acid form (5 and 10 μΜ), was used as a positive control. Incorporation experiment was carried out at 37 °C for 2 hours. After removal of medium and extensive washing, cells were harvested and crude total lipids were collected and saponified. Unlabeled cholesteryl oleate was used as a carrier in saponification. Cholesterol was recovered by extraction with H-hexane. Radioactivity was measured by using a liquid scintillation counter. 3

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Identification of Lovastatin in Pu-Erh Tea PET that exhibited inhibitory activity in cholesterol biosynthesis in cultured Hep G2 cells was again prepared in a larger scale. The powder was extracted with ethyl acetate (1:10, w/v). The ethyl acetate layer was concentrated and partially purified by silica gel column chromatography and preparative TLC (silica gel plates, 20x20-cm, 2-mm thickness; «-hexane: ethyl acetate=l:l, v/v). The silica gel, in the Rf range corresponding to lovastatin, was collected and extracted with ethyl acetate. Further purification was carried out by semipreparative reversed-phase HPLC (Qg, 8.0x250-mm) (22). Final identification of lovastatin in PET was carried out by mass spectrometry (Micromass Platform System; Manchester, UK).

DPPH Radical Scavenging The radical scavenging activity of PET was determined by using the stable radical DPPH (l,l-diphenyl-2-picrylhydrazyl). In a final volume of 300 μL, the reaction mixture contained 167 μΜ DPPH and PET (the powder was initially dissolved in water and finally diluted in 10% ethanol). After 15-min incubation in an incubator shaker, the absorption at 517 nm was taken and the value was corrected against a blank without DPPH (23). The radical scavenging activities of catechins, probucol, and trolox were also determined for comparison.

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Inhibition of Cu -induced L D L Oxidation Human sera were obtained from healthy adult donors after overnight fasting. LDL was isolated by ultracentrifugation with the density adjusted by NaBr (p 1.006-1.063). LDL fraction was dialyzed with PBS at 4 °C in darkness for 24 hr. LDL oxidation was induced by Cu (10 μΜ). LDL oxidation, determined by conjugated diene formation, was monitored by the increase of UV absorption at 234 nm (24,25). Antioxidant activity was determined by the capability to inhibit conjugated diene formation and prolong the lag phase (T| , min). A concentration dependent curve was obtained for the determination of IC value. Probucol and trolox were used as positive controls. 2+

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Animal Study Hamsters were acclimatized for 2 weeks in the 12-hour light dark controlled animal house before randomly assigned to five groups. Animals in

In Oriental Foods and Herbs; Ho, C., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.

92 each group (n=8) were fed with one of the five diets for 28 days. N , normal diet (Purina 5001); HC, high-cholesterol diet (normal diet plus 1% cholesterol, w/w); Sitosterol, HC plus 1.0% β-sitosterol (w/w); PET-1 (HC plus 1.0% PET, w/w), PET-2 (HC plus 2.0% PET, w/w), respectively. At the end of feeding period, animals were sacrificed after overnight fasting. Feces, collected in the last two days of feeding, were dried, ground, and saponified with an ethanolic KOH solution. During the 28-day feeding period, we adhered to the guideline for care and use of laboratory animals.

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Human Study 2

Sixteen healthy male adults (mean age, 23.2±2.2 yr.; BMI, 21.9±1.2 kg/m ) with normal plasma lipids (TC < 200 mg/dL, TG < 200 mg/dL, and plasma glucose < 126 mg/dL) were recruited with written consent (26,27). Volunteers were recommended to maintain their dietary habit and physical activity for at least 7 days before the experiment. Pu-Erh tea was prepared by extracting with boiling water (50 g Pu-Erh tea/1000 mL water) for 5 minutes. To reduce the bitter and mellow herbal taste, the extract was diluted 2.5 folds before providing to the volunteers. Volunteers were asked to drink 1000-mL tea extract (equivalent to the extract of 20 g Pu-Erh tea) each day for 7 days. Plasma samples were obtained on day 0 and day 7 after overnight fasting. Several volunteers are regular tea drinkers. During the 7-day period, Pu-Erh tea extract was the only beverage consumed except drinking water. No participant withdrew from this study. Plasma samples, before and after the 7-day drink period, were subjected to lipid and lipoprotein analysis.

General Lipid Analysis Serum cholesterol and TG levels were determined by enzymatic methods (28,29). Serum free fatty acid (FFA) level was determined by a colorimetric method (30). Human LDL was obtained by ultracentrifugation. The density range between 1.006-1.063 g/mL was collected as LDL. To determine the oxidative susceptibility in Cu -induced oxidation, LDL was dialyzed in phosphate-buffered saline (PBS) (10 mM, pH 7.4) and subjected to oxidation without prolonged storage (25,31). Hepatic cholesterol contents of hamsters were determined by a modified colorimetric assay after saponification and extraction (32). To avoid interference from plant sterols in the colorimetric assay, fecal cholesterol content was determined by reversed-phase HPLC (mobile phase: methanol : acetonitrile = 56:44, v/v). 2+

In Oriental Foods and Herbs; Ho, C., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.

93 Oxidative Susceptibility of Human L D L ex vivo 2+

Oxidation of LDL was initiated by adding with 10 μΜ Cu in PBS. The time course of LDL oxidation at ambient temperature was monitored by the formation of conjugated dienes, which was determined by the increase of UV absorption 234 nm. Lag phase (Ti , min) was defined as the intercept of the tangent drawn to the steepest segment of the propagation phase to the horizontal axis (24). ag

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α-Tocopherol Content in Human L D L Α 200-μ1 aliquot of LDL was added with an equal volume of ethanol. The mixture was immediately extracted with 1.0 mL n-hexane containing BHT (0.4 mg/mL) in darkness. The hexane layer was dried by a stream of nitrogen and the residue was dissolved in 100 μL· mobile phase (acetonitrile : tetrahydrofuran = 70/30, v/v). α-Tocopherol in the mixture was determined by reversed-phase HPLC (33). The detector wavelength was set at 292 nm. Retinyl acetate was used as an internal standard.

Statistical Analysis Results were expressed as mean+SEM. Statistical analyses were obtained by using unpaired t test or analysis of variance (ANOVA). A ρ value less than 0.05 was considered as statistically significant.

Results Inhibition of Cholesterol Synthesis in Hep G2 Cells Treatment of PET inhibited cholesterol synthesis in cultured Hep G2 cells (Table I). The potential of PET to inhibit cholesterol synthesis was demonstrated by the incorporation of [2- H]acetate into cholesterol. PET inhibited cholesterol biosynthesis in a dose-dependent manner (Table I). The conversion of R-[2C]mevalonate to cholesterol was not affected. Double-labeling experiment showed that PET inhibited cholesterol biosynthesis (40 μg/mL of PET had 56% inhibition) at the pre-mevalonate stage without affecting the post-mevalonate steps. In the assay system, fetal calf serum was maintained in DMEM. The IC 3

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In Oriental Foods and Herbs; Ho, C., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.

94 value of PET was 36 μg/mL. As a positive control, lovastatin, an HMG-CoA reductase inhibitor, inhibited cholesterol biosynthesis in cultured Hep G2 cells. The EGCG content in PET (0.59 mg/g tea), which was significantly lower than that in green tea (20.1 mg/g tea), was unable to inhibit cholesterol synthesis in Hep G2 cells to an equivalent extent (data not shown).

Lovastatin in Pu-Erh Tea Lovastatin (C24H 0 ; molecular weight 404.55) was identified in some batches of Pu-Erh tea. The identification was based on HPLC and mass spectrometry (APCI) after partial purification (Figure 2). The molecular ion of lovastatin (m/z) was clearly identified. Coupling with the inhibitory assay by using Hep G2 cells, we have examined several preparations of Pu-Erh tea. Results also showed that not all batches of PET Pu-Erh tea contained lovastatin (data not shown). The content of lovastatin in different supplies of Pu-Erh tea varied greatly from undetectable level to 0.86 mg/g dry weight of PET (aqueous extracts of Pu-Erh tea). For PET preparations exhibiting inhibitory activities in cholesterol biosynthesis, the inhibition was caused by lovastatin predominantly. Batches of Pu-Erh tea, which contained no or less lovastatin, also were less potent to inhibit cholesterol biosynthesis in cultured Hep G2 cells.

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DPPH Radical Scavenging The IC value of PET to scavenge DPPH radical was 8.3 μg/mL. The potency of PET was compared with those of tea catechins, trolox, and probucol (on equal weight basis). The DPPH radical scavenging activities were in the order: EGCG > trolox > green tea > Pu-Erh tea > black tea. As to the aqueous extract, the potency of Pu-Erh tea to scavenge DPPH radical was close to that of green tea (IC value 7.5 μg/mL) and better than black tea (IC value 14.3 μg/mL). 50

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Inhibition of LDL Oxidation in vitro PET exhibited strong antioxidant activity to inhibit LDL oxidation in vitrg. The antioxidant activities, based on the prolongation of lag phase in Cu induced LDL oxidation, were in the following order: trolox > PET> green tea > probucol > black tea. The IC values of the aqueous extracts of teas to inhibit Cu -induced LDL oxidation were PET (1.4 μg/mL), green tea (1.8 μg/mL), and 50

In Oriental Foods and Herbs; Ho, C., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.

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Figure 2. Identification of lovastatin in Pu-Erh tea. After partial purification by preparative TLC and semi-preparative reversed-phase HPLC, lovastatin in an enrichedfraction was identified by mass spectrometry. A, authentic lovastatin in reversed phase HPLC; B, peak corresponding to lovastatin in a preparativeTLC purifiedfraction; C, mass spectrum (m/z) of a semi-preparative HPLC enriched fraction containing lovastatin. Peak corresponding to lovastatin is marked by an asterisk. D, UV spectrum of lovastatin; E, UV spectrum of lovastatin collected from reversed-phase HPLC

In Oriental Foods and Herbs; Ho, C., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.

96 Table I. Inhibition of Cholesterol Biosynthesis in Hep G2 Cells by PET

Control (n=3) Lovastatin (n=4)

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1.82±0.02 (-65%) 0.84±0.06 (-84%) 3.97±0.17 (-24%) 2.29±0.09 (-56%) 1.58±0.04 (-70%)

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4.0 PET (n=4)

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[2- H]Acetate R-[2-' C]Mevalonate (10 dpm/ltf cells/h) 0.41±0.01 5.21±0.07

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0.38±0.02 (-6.8%) 0.38±0.02 (-7.8%) 0.39±0.01 (-5.1%) 0.39±0.02 (-5.3%) 0.38±0.02 (-6.5%)

NOTE: Human hepatoma cells (Hep G2) were cultured in DMEM. Cells were treated with [2-H]acetate (2.5 μα) and R-[2- C]mevalonate (1.3 μα) for 2 h. Lovastatin, in hydroxy acid form, was used as a positive control. Data are expressed as mean+SD (10 dpm/10 cells/h). The percentages of inhibition in treated groups, as compared with control, are shown in parentheses. 3

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black tea (3.3 μg/mL). The aqueous extracts of green tea and PET had approximately equal antioxidant activities to inhibit LDL oxidation in vitro.

Animal Study Hamsters fed with a high cholesterol diet (1%, w/w) were chosen as the animal model. There was no significant difference in body weight or adipose tissue weight among five animal groups after a 28-day feeding period (Table II). High cholesterol-diet feeding significantly increased the liver weight (5.3 g vs. 9.3 g, p